Imaging device having dimming element

ABSTRACT

Provided is a display device including an array substrate, a pixel, a dimming element, and a counter substrate. The pixel is located over the array substrate and includes a first electrode, a second electrode, and a liquid crystal layer over the first electrode and the second electrode. The dimming element is located over the array substrate and includes a third electrode, the liquid crystal layer over the third electrode, and a fourth electrode over the liquid crystal layer. The counter substrate is located over the fourth electrode.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/817,739, filed on Mar. 13, 2020. Further, this application is basedon and claims the benefit of priority from the prior Japanese PatentApplication No. 2019-51079, filed on Mar. 19, 2019, the entire contentsof which are incorporated herein by reference.

FIELD

The present invention relates to a display device and a manufacturingmethod of the display device. For example, the present invention relatesto a display device with a pixel including a liquid crystal element anda manufacturing method thereof.

BACKGROUND

A liquid crystal display device is represented as one of the mostcommonly used display devices. For example, liquid crystal displaydevices have been widely utilized as an interface of a variety ofelectronic devices including not only a television device but also acomputer, a tablet, a portable telephone, and the like.

In recent years, many small-size portable electronic terminals aredesigned so that the region (frame region or peripheral region) otherthan the display region is as small as possible in order to expand adisplay surface for improved display visibility and improveddesignability. In such a design strategy, the region required by theelements supporting the functions of the electronic terminals, such asan image-capturing element, a sensor, and an audio inputting/outputtingdevice, is strictly limited. Hence, it has been proposed to form acutoff or an opening in a part of a display and arrange animage-capturing element, a sensor, or the like therein. For example, itis disclosed in Japanese Patent Application Publication No. 2010-15015and Japanese Patent No. 2869452 that a display device is configured sothat a structure or a driving method of a portion of a display region isdifferent from that of the other portion to form a light-transmittingregion in the portion of the display region. The use of thislight-transmitting region allows a variety of elements to be arranged ata position overlapping with the display region.

SUMMARY

An embodiment of the present invention is a display device. The displaydevice possesses an array substrate, a pixel, a dimming element, and acounter substrate. The pixel is located over the array substrate andincludes a first electrode, a second electrode, and a liquid crystallayer over the first electrode and the second electrode. The dimmingelement is located over the array substrate and includes a thirdelectrode, the liquid crystal layer over the third electrode, and afourth electrode over the liquid crystal layer. The counter substrate islocated over the fourth electrode.

An embodiment of the present invention is a display device. The displaydevice possesses an array substrate, a pixel, a dimming element, a blackmatrix, a counter substrate, a first linear polarizing plate, a secondlinear polarizing plate, and a third linear polarizing plate. The pixelis located over the array substrate and includes a first electrode, asecond electrode, and a liquid crystal layer over the first electrodeand the second electrode. The dimming element is located over the arraysubstrate and includes a third electrode, a fourth electrode, and theliquid crystal layer over the third electrode and the fourth electrode.The black matrix is located over the liquid crystal layer. The countersubstrate is located over the black matrix. The first linear polarizingplate is located under the array substrate and overlaps with the pixel.The second linear polarizing plate is located over the counter substrateand overlaps with the pixel and the dimming element. The third linearpolarizing plate is located under the array substrate and overlaps withthe dimming element. The black matrix overlaps with the first linearpolarizing plate and the third linear polarizing plate.

An embodiment of the present invention is a manufacturing method of adisplay device. The manufacturing method includes forming a firstelectrode over an array substrate, forming an interelectrode insulatingfilm over the first electrode, forming a second electrode and a thirdelectrode over the interelectrode insulating film, forming a fourthelectrode over a counter electrode, and forming a liquid crystal layerbetween the array substrate and the counter substrate so that the firstelectrode, the second electrode, the third electrode, and the fourthelectrode are sandwiched by the array substrate and the counterelectrode, the fourth electrode overlaps with the third electrode, andthe first electrode and the second electrode are exposed from the fourthelectrode.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a schematic top view of a display device according to anembodiment of the present invention;

FIG. 2 is a schematic cross-sectional view of a display device accordingto an embodiment of the present invention;

FIG. 3 is a schematic top view of pixels and a dimming element of adisplay device according to an embodiment of the present invention;

FIG. 4 is a schematic top view of a pixel of a display device accordingto an embodiment of the present invention;

FIG. 5 is a schematic cross-sectional view of a pixel of a displaydevice according to an embodiment of the present invention;

FIG. 6 is a schematic top view of a dimming element of a display deviceaccording to an embodiment of the present invention;

FIG. 7 is a schematic cross-sectional view of a dimming element of adisplay device according to an embodiment of the present invention;

FIG. 8A and FIG. 8B are schematic perspective views for explaining theoperation of a display device according to an embodiment of the presentinvention;

FIG. 9A and FIG. 9B are schematic perspective views for explaining theoperation of a display device according to an embodiment of the presentinvention;

FIG. 10A and FIG. 10B are schematic perspective views for explaining theoperation of a display device according to an embodiment of the presentinvention;

FIG. 11A and FIG. 11B are respectively schematic top and cross-sectionalviews of a dimming element of a display device according to anembodiment of the present invention;

FIG. 12A and FIG. 12B are schematic top views of a dimming element of adisplay device according to an embodiment of the present invention;

FIG. 13A and FIG. 13B are respectively schematic cross-sectional and topviews of a dimming element of a display device according to anembodiment of the present invention;

FIG. 14 is a schematic top view of a dimming element of a display deviceaccording to an embodiment of the present invention;

FIG. 15 is a schematic cross-sectional view of a dimming element of adisplay device according to an embodiment of the present invention;

FIG. 16 is a schematic cross-sectional view of a pixel and a dimmingelement of a display device according to an embodiment of the presentinvention;

FIG. 17 is a schematic cross-sectional view of a pixel and a dimmingelement of a display device according to an embodiment of the presentinvention;

FIG. 18A and FIG. 18B are schematic perspective views for explaining theoperation of a display device according to an embodiment of the presentinvention;

FIG. 19A to FIG. 19C are schematic cross-sectional views for explaininga manufacturing method of a display device according to an embodiment ofthe present invention;

FIG. 20A and FIG. 20B are schematic cross-sectional views for explaininga manufacturing method of a display device according to an embodiment ofthe present invention;

FIG. 21A to FIG. 21C are schematic cross-sectional views for explaininga manufacturing method of a display device according to an embodiment ofthe present invention; and

FIG. 22 is a schematic cross-sectional view for explaining amanufacturing method of a display device according to an embodiment ofthe present invention.

DESCRIPTION OF EMBODIMENTS

Hereinafter, each embodiment of the present invention is explained withreference to the drawings. The invention can be implemented in a varietyof different modes within its concept and should not be interpreted onlywithin the disclosure of the embodiments exemplified below.

The drawings may be illustrated so that the width, thickness, shape, andthe like are illustrated more schematically compared with those of theactual modes in order to provide a clearer explanation. However, theyare only an example, and do not limit the interpretation of theinvention. In the specification and the drawings, the same referencenumber is provided to an element that is the same as that which appearsin preceding drawings, and a detailed explanation may be omitted asappropriate. A reference number is used when plural structures which arethe same as or similar to each other are collectively represented, whilea hyphen and a natural number are added behind the reference number whenthese structures are independently represented.

In the present specification and claims, when a plurality of films isformed by processing one film, the plurality of films may have functionsor roles different from each other. However, the plurality of filmsoriginates from a film formed as the same layer in the same process andhas the same layer structure and the same material. Therefore, theplurality of films is defined as films existing in the same layer.

In the specification and the claims, unless specifically stated, when astate is expressed where a structure is arranged “over” anotherstructure, such an expression includes both a case where the substrateis arranged immediately above the “other structure” so as to be incontact with the “other structure” and a case where the structure isarranged over the “other structure” with an additional structuretherebetween.

In the specification and the claims, an expression “a structure isexposed from another structure” means a mode in which a part of thestructure is not covered by the other structure and includes a modewhere the part uncovered by the other structure is further covered byanother structure.

First Embodiment

In the present invention, a structure of a display device 100 accordingto an embodiment of the present invention is described.

1. Outline Structure

The outline structure of the display device 100 is explained using FIG.1 and FIG. 2 . FIG. 1 is a schematic top view of the display device 100,and a schematic view of a cross section along a chain line A-A′ in FIG.1 is illustrated in FIG. 2 . As shown in FIG. 1 and FIG. 2 , the displaydevice 100 possesses a display module 300. The display device 100 mayfurther include a backlight unit 200 and a photoelectric transducer 400underneath the display module 300. In FIG. 2 , an example isdemonstrated where two photoelectric transducers 400 are provided.

1-1. Display Module 300

As shown in FIG. 2 , the display module 300 possesses a pair ofsubstrates 302 and 304 fixed to each other with a sealing material 306and a liquid crystal layer 308 sealed with the pair of substrates 302and 304 and the sealing material 306. Hereinafter, the substrates 302and 304 are referred to as an array substrate 302 and a countersubstrate 304, respectively. The sealing material 306 is sandwiched bythe array substrate 302 and the counter substrate 304 and provides asingle closed shape on the array substrate 302 as shown in FIG. 1 . Theinside of this closed shape is filled with the liquid crystal layer 308.Thus, a single liquid crystal layer 308 is structured in this singlespace formed by the array substrate 302, the counter substrate 304, andthe sealing material 306. A unit composed of this single crystal layer308, the array substrate 302, the counter substrate 304, and the sealingmaterial 306 is a liquid crystal cell. One display device 100 possessesa single liquid crystal cell.

The display module 300 may further include a pair of linear polarizingplates 310 and at least one pair of quarterwave plates (hereinafter,referred to as a λ/4 plate) 312 each sandwiching the array substrate 302and the counter substrate 304. The pair of λ/4 plates 312 is sandwichedby the pair of linear polarizing plates 310. In FIG. 2 , two pairs ofλ/4 plates 312 are illustrated. The detailed structure of the displaymodule 300 is described later.

1-2. Backlight Unit

As shown in FIG. 2 , the backlight unit 200 is disposed under the arraysubstrate 302 and possesses, as fundamental elements, a reflecting plate202, a light-guiding plate 204 over the reflecting plate 202, a lightsource 214 provided on a side surface of the light-guiding plate 204,and a variety of optical films formed over the light-guiding plate 204.The structure of the optical films is arbitrarily determined, and anoptical film in which a prism sheet 206 and a light-diffusing film 208are combined is demonstrated as an example in FIG. 2 . The backlightunit 200 is fixed to the display module 300 with an adhesive layer 212.

The light source 214 includes a light-emitting element such as alight-emitting diode and a cold-cathode tube. The light-emitting elementis preferred to have an emission wavelength covering the whole of thevisible light region. The backlight unit 200 and the light-guiding plate204 are arranged so that the light from the light-source 214 enters intothe light-guide plate 204, and the light-guiding plate 204 is configuredto diffuse and reflect the incident light in the inside thereof and touniformly emit the light in the direction toward the display module 300.The reflecting plate 202 is provided on an opposite side to the displaymodule 300 with respect to the light-guiding plate 204 and is configuredto reflect the light radiating to the opposite side to the displaymodule 300 and return the light to the light-guiding plate 204. Theprism sheet 206 is provided in order to collect the light emitted fromthe light-guiding plate 204 and radiate the collected light toward thefront direction of the display module 300, and a plurality ofprism-shaped depressions and projections is arranged in a stripe form ona surface thereof, for example. The light-diffusing film 208 is a memberfor making the light uniform and includes light-diffusing fine particlesand a polymer matrix fixing the fine particles.

At least one through hole 216 passing through at least the light-guidingplate 204 and the reflecting plate 202 is formed in the backlight unit200. The number of the through holes 216 may be the same as the numberof the photoelectric transducers 400, and an example is shown in FIG. 2where two through holes 216 respectively corresponding to twophotoelectric transducers 400 are disposed. In the example demonstratedin FIG. 2 , through holes overlapping with the through holes 216 arealso formed in the prism sheet 206 and the light-diffusing film 208. Itis not always necessary to form these through holes.

1-3. Semiconductor Element

The photoelectric transducer 400 is provided so as to overlap with thethrough hole 216. In FIG. 2 , a state is demonstrated where twophotoelectric transducers 400 respectively overlap with the throughholes 216. The function and the structure of the photoelectrictransducer 400 may be arbitrarily selected, and an image-capturingelement such as a CCD (Charge-Coupled Device) image sensor and a CMOS(Complementary Metal Oxide Semiconductor) image sensor, a photosensor,and the like are exemplified.

2. Structure of Display Module

Hereinafter, the structure of the display module 300 is explained indetail.

2-1. Layout

A variety of patterned semiconductor films, insulating films, andconductive films is stacked over the array substrate 302, and aplurality of pixels 322, a dimming element 324, circuits for drivingthese elements (scanning-line driver circuits 326 and signal-line drivercircuit 328), terminals 330, and the like are structured by these films(FIG. 1 ). An example is demonstrated in FIG. 1 in which two dimmingelements 324 are provided. However, the number of the dimming elements324 is not limited and may be one. Three or more dimming elements 324may be included. As described below, liquid crystal elements differentin operation mode from each other are respectively arranged in the pixel322 and the dimming element 324.

The pixel 322 is structured to allow a part of the light from thebacklight unit 200 to pass toward the outside of the display device 100and serves as a minimum unit providing information of a single color.The pixel 322 possesses a pixel circuit and the liquid crystal layer 308overlapping with the pixel circuit as fundamental elements. Thearrangement of the plurality of pixels 322 is not limited, and theplurality of pixels 322 may be arranged in a variety of arrangementssuch as the tripe arrangement, the mosaic arrangement, and the deltaarrangement. A region defined by the plurality of pixels 322 is adisplay region 320. The pixels 322 are arranged so as not to overlapwith the thorough hole 216.

A schematic top view of the dimming element 324 and the peripherythereof is shown in FIG. 3 . The dimming element 324 is located in thedisplay region 320, and one dimming element 324 is arranged so as to besurrounded by the plurality of pixels 322. The dimming element 324 maybe configured so that the size (area) thereof is larger than that ofeach pixel 322. The shape of the dimming element 324 is not limited to acircular shape shown in FIG. 3 and may be arbitrarily determined. Forexample, an arbitral shape such as a quadrangle including a square, arectangle, a trapezoid, and the like, a polygon, and an ellipse may beemployed.

The dimming element 324 is arranged at the position overlapping with thethrough hole 216. Thus, the dimming element 324 may overlap with thephotoelectric transducer 400. A pixel circuit having a differentstructure from that of the pixel circuit in the pixel 322 is also formedin the dimming element 324, and the dimming element 324 possesses thispixel circuit and the liquid crystal layer 308 overlapping with thepixel circuit as fundamental elements. The dimming element 324 has afunction to control transmissivity of outside light, which allows theamount of the light incident on the photoelectric transducer 400 to beadjusted.

A variety of signal lines (a gate line, an image-signal line, aninitializing signal line, a power source line, and the like), which isnot illustrated, extend from the scanning-line driver circuits 326 andthe signal-line driver circuit 328 to the display region 320, and thesesignal lines are electrically connected to the respective pixels 322 andthe dimming element 324. A connector such as a flexible printed circuitsubstrate (FPC), which is not illustrated, is connected to the terminals330, and the signals and a power source supplied from an externalcircuit (not illustrated) are provided to the scanning-line drivercircuits 326, the signal-line driver circuit 328, the pixels 322, andthe dimming element 324 through the connector and the terminals 330. Thescanning-line driver circuits 326 and the signal-line driver circuit 328operate the pixel circuits in the pixels 322 and the dimming element 324on the basis of the supplied signals and power source, by whichorientation of the liquid crystal molecules in the liquid crystal layer308 is controlled, the amount of the light provided from the backlightunit 200 is controlled in the pixels 322, and the amount of the incidentoutside light is controlled in the dimming element 324.

2-2. Pixel

An example of the layout of the pixels 322 is shown in FIG. 4 , whereasa schematic view of a cross section along a chain line B-B′ in FIG. 4 isshown in FIG. 5 . As shown in these figures, the pixel circuit in thepixel 322 includes a pixel electrode 350, a common electrode 348, atransistor 346 electrically connected to the pixel electrode 350, theliquid crystal layer 308 provided over the pixel electrode 350 and thecommon electrode 348, orientation films (a first orientation film 370-1and a second orientation film 370-2), and the like. The pixel 322 iselectrically connected to the gate line 340 extending from thescanning-line driver circuit 326, the image signal line 342 extendingfrom the signal-line driver circuit 342, and the power-source line 344.The pixel circuit shown in these figures is merely an example and mayinclude other elements such as a storage capacitor and a transistor.

As shown in FIG. 5 , the pixel circuit is disposed over the arraysubstrate 302 through an undercoat 360. The array substrate 302 includesa material selected from glass, quartz, a plastic containing a polymersuch as a polyamide, or the like. The undercoat 360 functions as aprotection film for preventing diffusion of impurities in the arraysubstrate 302 and is composed of one or a plurality of films including asilicon-containing inorganic compound such as silicon oxide and siliconnitride.

The transistor 346 is structured by a semiconductor film 352, a part ofa gate insulating film 362, a part of the gate line 340, a part of aninterlayer insulating film 364, a part of the image-signal line 342, adrain electrode 354, and the like. A part of the gate line 340overlapping with the semiconductor film 352 functions as a gateelectrode of the transistor 346, while a part of the aforementionedimage-signal line 342 functions as a source electrode of the transistor346. Openings reaching the semiconductor film 352 are formed in the gateinsulating film 362 and the interlayer insulating film 364, and thedrain electrode 354 and the source electrode are electrically connectedto the semiconductor film 352 through these openings. In the exampledemonstrated here, the transistor 346 is a top-gate type transistor.However, the transistor 346 may be a transistor having another structure(a bottom-gate type transistor, etc.).

A leveling film 366 is disposed over the transistor 346, by whichdepressions and projections formed by the transistor 346 are absorbed toprovide a flat surface. The leveling film 366 includes a polymermaterial such as an acrylic resin, an epoxy resin, a polysiloxane resin,and a polyamide.

The common electrode 348 is arranged over the leveling film 366. Thecommon electrode 348 is formed to be shared by the plurality of pixels322. For example, the common electrode 348 is arranged parallel to thegate line 340 and shared by the plurality of pixels 322 connected to onegate line 340 as shown in FIG. 4 . Although not illustrated, the commonelectrode 348 may be arranged parallel to the image-signal line 342 tobe shared by the plurality of pixels 322 connected to one image-signalline 342 or may be formed to be shared by all of the pixels 322.

The power-source line 344 in contact with the common electrode 348 isdisposed over the common electrode 348. The power-source line 344 may bearranged to overlap with the image-signal line 342. A potential (Vcom)slightly lower than an intermediate potential between the maximum andminimum potentials of the image signal is supplied to the image-signalline 342, and this potential is provided to the common electrode 348.Although not illustrated, the power-source line 344 may be arrangedunder the common electrode 348.

The pixel electrode 350 is formed over the common electrode 348 and thepower-source line 344 through an interelectrode insulating film 368. Thepixel electrode 350 is electrically connected to the drain electrode 354through an opening formed in the leveling film 366 and theinterelectrode insulating film 368. With this structure, the imagesignal supplied to the image-signal line 342 is provided to the pixelelectrode 350 through the transistor 346, and the potential of the pixelelectrode 350 is independently controlled for every pixel 322 inaccordance with the image signal. As shown in FIG. 4 , the pixelelectrode 350 possesses a slit having a closed shape, and a part of thepixel electrode 350 is exposed from the slit. Although not illustrated,the pixel electrode 350 may have a cutoff instead of a slit.Alternatively, the pixel electrode 350 may simultaneously possess a slitand a cutoff. Note that a slit is an opening formed in the pixelelectrode 350 and having a closed shape, and its outer circumferencecorresponds to an internal circumference of the pixel electrode 350.When this outer circumference of the opening is a part of an outercircumference of the pixel electrode 350, the opening is defined as acutoff.

The first orientation film 370-1 is disposed over the pixel electrode350. The first orientation film 370-1 has a polymer such as a polyimide,and a surface thereof is turned to control the orientation of the liquidcrystal molecules included in the liquid crystal layer 308.Specifically, a rubbing treatment is performed on the surface of thefirst orientation film 370-1. Alternatively, polarized ultraviolet lightis applied once or a plurality of times in order to orient the liquidcrystalline unit in the first orientation film 370-1 when the firstorientation film 370-1 is formed using a photo-curable resin having aliquid crystalline unit. Alternatively, a film of a photo-decomposabletype polyimide or the like may be formed, and then polarized ultravioletlight may be applied. Hereinafter, the treatments for orientationcontrol performed on the orientation films 370 are collectively referredto an orientation treatment. The direction in which the liquid crystalmolecules orient over the first orientation film 370-1, which issubjected to the orientation treatment, in the absence of an electricfield is referred to an orientation treatment direction.

A color filter 374 and a black matrix 376 are formed over the countersubstrate 304. A color is provided to the light from the backlight unit200 by the color filter 374, which enables the pixel 322 to providecolor information. The color filter 374 is configured so that opticalproperties thereof are different between the adjacent pixels 322. Theblack matrix 376 is configured to exhibit a low transmissivity withrespect to visible light or not to substantially transmit visible lightand is formed so as to cover the transistor 346, the image-signal line342, and the gate line 340. As an optional element, an overcoat 372covering the color filter 374 and the black matrix 376 may be disposedover the counter substrate 304. The counter substrate 304 furtherpossesses the second orientation film 370-2 covering the color filter374 and the black matrix 376. Similar to the first orientation film370-1, the orientation treatment is also performed on the secondorientation film 370-2, and the orientation treatment direction thereofis the same as that of the first orientation film 370-1.

The liquid crystal layer 308 is provided between the array substrate 302and the counter substrate 304, and the pixel electrode 350, the commonelectrode 348, the first orientation film 370-1, and the secondorientation film 370-2 are sandwiched by the array substrate 302 and thecounter electrode 304. The liquid crystal layer 308 includes apositive-type liquid crystal having a positive dielectric anisotropy. Asdescribed above, the liquid crystal layer 308 is sealed in the spaceformed by the sealing material 306, the array substrate 302, and thecounter substrate 304, and the display device 100 possesses a singleliquid crystal cell. Hence, one liquid crystal layer 308 is shared byall of the pixels 322.

A distance between the array substrate 302 and the counter substrate 304is controlled by a spacer 378 formed over the array substrate 302, forexample. The spacer 378 includes a polymer such as an acrylic resin andan epoxy resin and is formed for every pixel 322 or for every pluralpixels 322. The spacer 378 may be formed over the array substrate 302.Alternatively, a sphere spacer which is not fixed to the array substrate302 and the counter substrate 304 may be used.

As described above, the display device 100 possesses the pair of linearpolarizing plates 310 (a first linear polarizing plate 310-1 and asecond linear polarizing plate 310-2). The pair of linear polarizingplates 310 overlaps with the display region 320 and is arranged so as tosandwich the pixels 322. More specifically, the pair of linearpolarizing plates 310 is arranged so as to sandwich the array substrate302 and the counter substrate 304 and overlap with the pixel electrode350 and the counter electrode 348. In the display device 100, the pairof linear polarizing plates 310 has a crossed Nichol relationship. Thatis, the pair of linear polarizing plates 310 is arranged so that thetransmission axes thereof perpendicularly intersect with each other.

In each pixel 322, the initial orientation of the liquid crystalmolecules included in the liquid crystal layer 308 is mainly determinedby the orientation treatment directions of the first orientation film370-1 and the second orientation film 370-2. In the absence of anelectric field, the liquid crystal molecules orient along theorientation treatment directions substantially parallel to a surface ofthe array substrate 302. When a potential difference is provided betweenthe pixel electrode 350 and the common electrode 350, this initialorientation varies. That is, the electric field generated between thepixel electrode 350 and the common electrode 348 and substantiallyparallel to the surface of the array substrate 302 causes the liquidcrystal molecules to rotate in a plane substantially parallel to thesurface of the array substrate 302. Accordingly, the orientationdirection of the liquid crystal molecules changes, and the control ofthis change with the potential difference between the pixel electrode350 and the common electrode 348 enables the light transmissivity of theliquid crystal layer 308 to be controlled, thereby realizing gradationdisplay. Accordingly, an FFS (Fringe Field Switching) liquid crystalelement is formed in each pixel 322. Here, a pair of electrodes and aportion of a liquid crystal layer driven by the pair of electrodes arecollectively defined as a liquid crystal element in the presentspecification. Therefore, each pixel 322 possesses a liquid crystalelement including the pixel electrode 350, the common electrode 348, anda part of the liquid crystal layer 308 driven by the pixel electrode 350and the common electrode 348

Although not illustrated, the liquid crystal element in each pixel 322may be an IPS (In-Plane Switching) liquid crystal element. In this case,the common electrode 348 also has a slit and/or a cutoff, and the pixel322 is configured so that the common electrode 348 exists in the samelayer as the pixel electrode 350.

2-3. Dimming Element

A top view of the dimming element 324 is shown in FIG. 6 , whereas aschematic view of a cross section along a chain line C-C′ in FIG. 6 isshown in FIG. 7 . As demonstrated in these figures, the pixel circuit ofthe dimming element 324 includes a lower electrode 349, an upperelectrode 351 overlapping with the lower electrode 349, and the liquidcrystal layer 308 arranged between the lower electrode 349 and the upperelectrode 351. The dimming element 324 is electrically connected to adimming-controlling line 358 extending from the signal-line drivercircuit 328. The dimming-controlling line 358 is provided with adimming-controlling signal from the signal-line driver circuit 328, anda potential of this signal is supplied to the lower electrode 349through the dimming-controlling line 358. The lower electrode 349 may beformed so as to cover the whole of the through hole 326 as shown in FIG.6 . Alternatively, although not illustrated, the lower electrode 349 maybe formed so as to cover the whole of the light-receiving surface of thephotoelectric transducer 400.

Similar to the pixel circuit of the pixel 322, the pixel circuit of thedimming element 324 is also disposed over the array substrate 302through the undercoat 360. The dimming element 358 is formed over thearray substrate 302 via the undercoat 360 as well as the gate insulatingfilm 362 and the interlayer insulating film 364 extending from the pixel322, over which the leveling film 366 is arranged. An opening 356reaching the dimming-controlling line 358 is formed in the leveling film366, and the lower electrode 349 is arranged over the leveling film 366so as to cover this opening 356, by which the lower electrode 349 andthe dimming-controlling line 358 are electrically connected to eachother. In the present embodiment, one lower electrode 349 is arranged inone dimming element 324. In other words, one dimming element 324possesses one liquid crystal element including one lower electrode 349,one upper electrode 351 overlapping with the lower electrode 349, and apart of the liquid crystal layer 308 therebetween.

The lower electrode 349 is covered by the first orientation film 370-1extending from the pixel 322. Therefore, the first orientation film370-1 over the lower electrode 349 is shared by the pixel 322, and theorientation treatment direction thereof is the same as that in the pixel322.

The counter substrate 304 is provided with the upper electrode 351. Theupper electrode 351 may be configured so that the same potential (Vcom)as that of the common electrode 348 is supplied or a potential differentfrom that of the common electrode 348 is supplied. When the overcoat 372is disposed in the pixel 322, the upper electrode 351 is formed over thecounter electrode 304 through the overcoat 372. The second orientationfilm 370-2 extending from the pixel 322 and covering the upper electrode351 is also formed over the counter substrate 304. Similar to the firstorientation film 370-1, this second orientation film 370-2 is alsoshared by the pixel 322, and the orientation treatment direction thereofis the same as that in the pixel 322. Note that the color filter 374 maynot be formed in the dimming element 324. In this case, the overcoat 372may be in contact with the counter substrate 304 as shown in FIG. 7 .The black matrix 376 may be formed in the dimming element 324 so as tooverlap with the dimming-controlling line 358, for example. Although notillustrated, similar to the pixels 322, a transistor electricallyconnected to the lower electrode 349 and the dimming-controlling line358 may be provided therebetween to supply the dimming-controllingsignal to the lower electrode 349 through the transistor.

The liquid crystal layer 308 is arranged between the lower electrode 349and the upper electrode 351, and the lower electrode 349, the upperelectrode 351, the first orientation film 370-1, and the secondorientation film 370-2 are sandwiched by the array substrate 302 and thecounter substrate 304. As described above, the sealing material 306forms a single closed shape over the array substrate 302. Hence, theliquid crystal layer 308 is not divided between the dimming element 324and the pixel 322 and is shared by the dimming element 324 and the pixel322. In other words, one liquid crystal layer 308 is shared by all ofthe pixels 322 and the dimming element 324. Similar to the pixel 322,the spacer 378 may be disposed in the dimming element 324 to maintainthe distance between the lower electrode 349 and the upper electrode351.

As described above, the display device 100 possesses the pair of linearpolarizing plates 310 and the pair of λ/4 plates 312. The pair of λ/4plates (a first λ/4 plate 312-1 and a second λ/4 plate 312-2) isrespectively arranged under the array substrate 302 and over the countersubstrate 304 to sandwich the dimming element 324. The pair of λ/4plates 312 does not overlap with the pixel 322. In other words, thepixels 322 are exposed from the pair of λ/4 plates 312. The slow axes ofthe pair of λ/4 plates 312 perpendicularly intersect with each other.

In addition, the pair of linear polarizing plates 310 is respectivelydisposed under the array substrate 302 and over the counter substrate304 to sandwich the dimming element 324 and the pair of λ/4 plates 312.Therefore, in the region where the dimming element 324 is formed, thepair of linear polarizing plates 310 and the pair of λ/4 plates 312overlap with each other, and the latter is sandwiched by the former.Since the pair of linear polarizing plates 310 is arranged so as tooverlap with the pixels 322, the pair of linear polarizing plates 310 isshared by the pixel 322 and the dimming element 324. Similar to thepixel 322, the transmission axes of the linear polarizing plates 310also perpendicularly intersect with each other in the dimming element324. Moreover, the direction of the transmission axis of the firstlinear polarizing plate 310-1 is the same between the pixel 322 and thedimming element 324, and the direction of the transmission axis of thesecond linear polarizing plate 310-2 is also the same between the pixel322 and the dimming element 324. The slow axes of the pair of λ/4 plates312 respectively shift from the transmission axes of the pair of linearpolarizing plates 310 by 45°.

In the dimming element 324, the initial orientation of the liquidcrystal molecules included in the liquid crystal layer 308 is alsomainly determined by the orientation treatment directions of the firstorientation film 370-1 and the second orientation film 370-2. In theabsence of an electric field, the liquid crystal molecules orient alongthe orientation treatment direction substantially parallel to thesurface of the array substrate 302. Since the orientation treatmentdirections of the orientation films 370 are the same as each otherbetween the pixel 322 and the dimming element 324, the orientationdirection of the liquid crystal molecules is also the same as eachother. When a potential difference is provided between the lowerelectrode 349 and the upper electrode 351, this initial orientationvaries. That is, the electric field generated between the lowerelectrode 349 and the upper electrode 351 and substantiallyperpendicular to the surface of the array substrate 302 causes theliquid crystal molecules to be raised (tilted) from the surface of thearray substrate 302 so as to diagonally or perpendicularly orient fromthe surface. The control of this change in orientation state with thepotential difference between the lower electrode 349 and the upperelectrode 351 enables the control of the light transmissivity of theliquid crystal layer 308. Accordingly, an ECB (Electrically ControlledBirefringence) liquid crystal element is formed in the dimming element324. Hence, the display device 100 possesses two kinds of liquid crystalelement different in operation mode.

3. Operation

Operation of the dimming element 324 is explained using FIG. 8A and FIG.8B, whereas operation of the pixel 322 is explained using FIG. 9A andFIG. 9B. For visibility, the upper electrode 351 and the lower electrode349 in the dimming element 324 are not illustrated in these figures.Although the linear polarizing plates 310 and the λ/4 plates 312 areseparately illustrated, this is merely for convenience of explanation,and these items may be in contact with each other. The dotted arrowsshown over the linear polarizing plates 310 and the λ/4 plates 312respectively express the transmission axis and the slow axis thereof,and the solid arrows express the polarizing direction of the light.

3-1. Dimming Element

(1) Initial State

A schematic perspective view of the dimming element 324 in the initialstate, i.e., in an off state, is shown in FIG. 8A. In this state, theorientation of the liquid crystal molecules illustrated as ellipses isdetermined by the orientation treatment directions of the firstorientation film 370-1 and the second orientation film 370-2. Since theorientation treatment directions of the first orientation film 370-1 andthe second orientation film 370-2 are the same as each other, the liquidcrystal molecules substantially orient along the orientation treatmentdirection in the absence of an electric field.

Here, a case is considered where the light proceeds from the arraysubstrate 302 side (i.e., the side of the first linear polarizing plate310-1) toward the counter electrode 304 side (i.e., the side of thesecond linear polarizing plate 310-2). This light indicated by thehollow arrow becomes linearly polarized light (a) when passing throughthe first linear polarizing plate 310-1. When this linearly polarizedlight (a) next enters into the first λ/4 plate 312-1, the phase shiftsby π/2 because the slow axis of the first λ/4 plate 312-1 shifts fromthe transmission axis of the first linear polarizing plate 310-1 by 45°.As a result, the light becomes circularly polarized light (b) whenpassing through the first λ/4 plate 312-1. When this circularlypolarized light (b) passes through the liquid crystal layer 308, thislight becomes inverted circularly polarized light (c) because the phaseis π-retarded due to the anisotropy of the refractive index of theliquid crystal molecules included in the liquid crystal layer 308. Whenthis circularly polarized light (c) further enters into the second λ/4plate 312-2, this light is −π/2-retarded because the first λ/4 plate312-1 and the second k/4 plate 312-2 are in an orthogonal relationship.As a result, the phase difference from the light incident on the firstλ/4 plate 312-1 becomes n, and therefore, the circularly polarized light(c) becomes linearly polarized light (d). The polarizing axis at thistime perpendicularly intersects with that of the polarized light (a)formed by the first linear polarizing plate 310-1. Since the firstlinear polarizing plate 310-1 and the second linear polarizing plate310-2 are in the cross Nichol relationship with each other, the linearlypolarized light (d) generated when passing through the second λ/4 plate312-2 is capable of passing through the second linear polarizing plate310-2. The same is applied when the outside light proceeds from thecounter substrate 304 side to the array substrate 302 side. Thus, theoutside light is capable of passing through the first linear polarizingplate 310-1. Hence, the light can pass through the dimming element 324,and the dimming element 324 functions as the so-called normally whiteelement.

(2) Operation

A schematic perspective view of the dimming element 324 in the casewhere a potential difference is provided between the lower electrode 349and the upper electrode 351, that is, in an on state, is illustrated inFIG. 8B. When this potential difference exceeds the threshold voltage,the liquid crystal molecules gradually rise from the surface of thearray substrate 302, and the tilt angle thereof increases withincreasing potential difference. Thus, the birefringence decreases withrespect to the light incident on the liquid crystal molecules. When thebirefringence is 0, the circularly polarized light (b) generated whenpassing through the first λ/4 plate 312-1 enters the second linearpolarizing plate 310-2 while maintaining its polarization property.Although this circularly polarized light (c) is converted into thelinearly polarized light (d) by the second linear polarizing plate310-2, the polarizing axis at this time is the same as the polarizingaxis of the linearly polarizing light (a) formed by the first linearpolarizing plate 310-1 and perpendicularly intersects with thetransmission axis of the second linear polarizing plate 310-2.Therefore, the light incident on the first linear polarizing plate 310-1cannot pass through the dimming element 324. The behavior of the outsidelight incident on the second linear polarizing plate 310-2 is also thesame and cannot pass through the first linear polarizing plate 310-1.

The birefringence of the liquid crystal molecules with respect to thelight incident on the liquid crystal molecules is controlled by the tiltangle of the liquid crystal molecules, and the tilt angle is determinedby the potential difference provided between the upper electrode 351 andthe lower electrode 349. Therefore, the control of this potentialdifference using the dimming-controlling signal enables thetransmissivity of the dimming element 324 to be adjusted.

As described above, the through hole 216 formed in the light-guidingplate 204 and the reflecting plate 202 is locate in the region where thedimming element 324 is provided. Hence, when the dimming element 324 isin an off state (i.e., normally white), the outside light is capable ofpassing through the dimming element 324, which enables sensing of theoutside light, capturing an image, and the like by utilizing thephotoelectric transducer 400 arranged in or under the through hole 216.On the other hand, it is possible to adjust the transmissivity of thedimming element 324 by driving the dimming element 324 while controllingthe potential difference between the upper electrode 351 and the lowerelectrode 349, which allows the dimming element 324 to function as aneutral density (ND) filter or a shutter. When the dimming element 324functions as a shutter, the outside light reflected by the photoelectrictransducer 400 can be shielded. Thus, it is possible to exclude anadverse influence on the display produced by the pixels 322 as describedbelow.

In addition, it is not necessary to form a slit or a cutoff in the lowerelectrode 349 in the dimming element 324 of the display device 100, andthe lower electrode 349 has the same thickness in almost all of thedimming element 324. Moreover, the lower electrode 349 is arranged tocover the whole of the through hole 216 or all of the light-receivingsurface of the photoelectric transducer 400 as described above.Therefore, it is possible to avoid the generation of a refractive indexdistribution caused by a slit or a cutoff, and no adverse influence isprovided to the outside light incident on the dimming element 324.Accordingly, when an image-capturing element is used as thephotoelectric transducer 400, no adverse influence such as generation ofa fringe or unevenness is exerted on the captured image, and ahigh-quality image can be obtained.

3-2. Pixel

(1) Initial State

A schematic perspective view of the pixel 322 in the off state is shownin FIG. 9A. Similar to the dimming element 324, the orientation of theliquid crystal molecules is determined by the orientationcharacteristics of the first orientation film 370-1 and the secondorientation film 370-2. Since the orientation treatment directions ofthe first orientation film 370-1 and the second orientation film 370-2are the same as each other, the liquid crystal molecules substantiallyorient along the orientation treatment direction in the absence of anelectric field.

Here, a case is considered where the light from the backlight unit 200is incident on the side of the first linear polarizing plate 310-1 andproceeds toward the side of the second linear polarizing plate 310-2.The light derived from the backlight unit 200 and indicated by thehollow arrow becomes linearly polarized light (a) parallel to thetransmitting axis when passing through the first linear polarizing plate310-1. Since no λ/4 plate 312 is provided in the pixel 322, thislinearly polarized light (a) is next incident on the liquid crystallayer 308. When the orientation treatment is performed on theorientation films 370 so that the orientation treatment directionsperpendicularly intersect with the transmission axis of the first linearpolarizing plate 310-1, the polarizing axis of the linearly polarizedlight (a) almost perpendicularly intersect with the orientationdirection of the liquid crystal molecules. Hence, no birefringenceappears, and no phase retardation of the light occurs. As a result, thelinearly polarized light (a) enters the second linear polarizing plate310-2 while maintaining its polarizing axis and intensity. However,since the transmission axis of the second linear polarizing plate 310-2perpendicularly intersects with the polarizing axis of the linearpolarizing plate 310-1, the light incident on the second linearpolarizing plate 310-2 (b) is absorbed by the second linear polarizingplate 310-2 and does not radiate from the pixel 322. Therefore, thepixel 322 is in the so-called normally off state in the off state.

(2) Operation

A schematic perspective view of the pixel 322 in the case where apotential difference is provided between the pixel electrode 350 and thecommon electrode 348, that is in an on state, is illustrated in FIG. 9B.This potential difference generates an electric field substantiallyparallel to the surface of the array substrate 302, and the liquidcrystal molecules rotate in the plane parallel to the surface of thearray substrate 302 due to the dielectric anisotropy of the liquidcrystal molecules. Hence, the polarizing axis of the linearly polarizedlight (a) incident on the liquid crystal layer 308 and the orientationdirection of the liquid crystal molecules shift from each other, and thephase retardation of the light incident on the liquid crystal layer 308occurs. Here, the thickness of the liquid crystal layer 308 iscontrolled according to the refractive indexes of the liquid crystalmolecules in the long axis direction and the short axis direction sothat the phase retardation is approximately π in the display device 100.Therefore, the light which has passed through the liquid crystal layerbecomes the linearly polarized light (b) obtained by rotating thepolarizing axis of the linearly polarized light (a). When theorientation of the liquid crystal molecules rotates by 90°, thepolarizing axis of this linearly polarized light (b) perpendicularlyintersects with the polarizing axis of the linearly polarized light (a).In addition, the first linear polarizing plate 310-1 and the secondlinear polarizing plate 310-2 are in the cross Nichol relationship.Thus, the linearly polarized light radiating from the liquid crystallayer 308 is capable of passing through the second linear polarizingplate 310-2.

The amount of the extracted light depends on the rotation angle of theliquid crystal molecules, and the rotation angle can be controlled bythe potential difference between the pixel electrode 350 and the commonelectrode 348 based on the potential of the image signal. Hence,gradation can be obtained in each pixel 322 by controlling thispotential difference. Moreover, since the color filter 374 with adifferent optical property is formed in every pixel as described above,it is possible to control the gradation for every color, which enablesfull-color display on the display region 320.

As described above, since the pixel 322 disposed in the display region320 is normally off in the display device 100, display having a highcontrast can be realized. Furthermore, an FFS liquid crystal element isformed in the pixel 322, it is possible to perform display withexcellent viewing-angle characteristics. Therefore, high-qualityfull-color display is attainable by the display device 100.

Moreover, the dimming element 324 is arranged so as to be surrounded bythe pixels 322, and the photoelectric transducer 400 such as animage-capturing element can be disposed so as to overlap with thedisplay region 320. Therefore, the photoelectric transducer 400 is notrequired to be arranged in the frame region, which allows the frameregion to be reduced or excluded and an area of the display region 320relative to the whole of the display device to be increased. As aresult, an electric apparatus with a large display region 320 andexcellent designability can be provided. In addition, it is alsopossible to control the light transmissivity of the dimming element 324,the amount of the light incident on the photoelectric transducer 400 canbe appropriately adjusted without decreasing display quality caused bythe dimming element 324.

4. Modified Example

The display device 100 may possess a pair of halfwave plates(hereinafter, referred to as a λ/2 plate) 314 instead of the pair of λ/4plates 312. The structure and operation in this case are explained usingFIG. 10A and FIG. 10B. FIG. 10A and FIG. 10B are respectively schematicperspective views of the display device 100 in the initial state and inoperation and respectively correspond to FIG. 8A and FIG. 8B.

The pair of λ/2 plates 314 is disposed so as to sandwich the dimmingelement 324 and is sandwiched by the pair of linear polarizing plates310. The pair of λ/2 plates 314 is arranged so that the slow axis of theλ/2 plate (first λ/2 plate 314-1) arranged on the side of the arraysubstrate 302 shifts from that of the first linear polarizing plate310-1 by 22.5°, and, in a similar way, the λ/2 plate (second λ/2 plate314-2) arranged on the side of the counter substrate 304 shifts fromthat of the second linear polarizing plate 310-2 by 22.5°. Hence, theslow axes of the λ/2 plates 314 are in an orthogonal relationship, andthe pair of linear polarizing plates 310 is also in the cross Nicholrelationship.

(1) Initial State

Similar to the case using the pair of λ/4 plates 312 (FIG. 8A), theliquid crystal molecules substantially orient along the orientationtreatment direction in the off state (FIG. 10A). The light proceedingfrom the side of the linear polarizing plate 310-1 becomes linearlypolarizing light (a) when passing through the first linear polarizingplate 310-1. The phase π-shifts when this linearly polarized light (a)next enters the first λ/2 plate 314-1. However, since the slow axis ofthe first λ/2 plate 314-1 shifts from the transmission axis of the firstlinear polarizing plate 310-1 by 22.5°, the polarizing axis of thelinearly polarized light (a) which has passed through the first λ/2plate 314-1 shifts by π/2 from the transmission axis of the first linearpolarizing plate 310-1, that is, by 45° from the transmission axis ofthe first linear polarizing plate 310-1, and the linear polarizing light(a) becomes linearly polarized light (b). When this linearly polarizedlight (b) passes through the liquid crystal layer 308, further phaseretardation occurs. Here, the thickness of the liquid crystal layer 308is controlled according to the refractive indexes of the liquid crystalmolecules in the long axis direction and the short axis direction sothat the phase retardation is approximately Tr in the display device100. Hence, the polarizing axis further shifts by 90°, and the linearlypolarized light (b) becomes linearly polarizing light (c) when thelinearly polarized light (b) passes through the liquid crystal layer308. When this linearly polarizing light (c) further enters the secondλ/2 plate 314-2, a π phase difference arises. However, since the slowaxis of the second λ/2 plate 314-2 shifts from the transmission axis ofthe second linear polarizing plate 310-2 by an angle of 25.5°, a π/2phase difference is provided. As a result, the polarizing axis shifts by45°, and the linearly polarized light (c) becomes linearly polarizedlight (d) having a polarizing axis perpendicularly intersecting with thetransmission axis of the first linear polarizing plate 310-1. Thispolarizing axis perpendicularly intersects with the transmission axis ofthe second linear polarizing plate 310-2, and the light cannot passthrough the second linear polarizing plate 310-2. Thus, the dimmingelement 324 is in the so-called normally black state in the off state.

(2) Operation

When the potential difference provided between the lower electrode 349and the upper electrode 351 exceeds the threshold voltage, the liquidcrystal molecules gradually rise from the surface of the array substrate302, and the tilt angle thereof increases with increasing potentialdifference. Thus, the birefringence decreases with respect to the lightincident on the liquid crystal molecules. When the birefringence is 0,the polarization property of the linearly polarized light (b) generatedwhen passing through the first λ/2 plate 314-1 is maintained, and thelinearly polarized light (c) is incident on the second λ/2 plate 314-2.This linearly polarized light (c) is converted into linearly polarizedlight (d) by the second λ/2 plate 314-2. However, since the slow axis ofthe second λ/2 plate 314-2 shifts from the transmission axis of thesecond linear polarizing plate 310-2 by 22.5°, the polarizing axisthereof is the same as the transmission axis of the linear polarizingplate 310-2. Therefore, this linearly polarized light (d) is capable ofpassing through the second linear polarizing plate 310-2. Similarly, thebehavior of the light incident from the second linearly polarizing plate310-2 is able to pass through the first linear polarizing plate 310-1.

The birefringence of the liquid crystal molecules with respect to thelight incident on the liquid crystal molecules is controlled by the tiltangle of the liquid crystal molecules, and the tilt angle is determinedby the potential difference provided between the upper electrode 351 andthe lower electrode 349. Therefore, the control of this potentialdifference using the dimming-controlling signal enables thetransmissivity of the dimming element 324 to be adjusted. For example,when the dimming element 324 is in an off state (i.e., in a normallyblack state), the light reflected by the photoelectric transducer 400can be shielded because the outside light cannot pass through thedimming element 324, which prevents an adverse influence on the displayproduced by the pixels 322. In addition, the transmissivity of thedimming element 324 can be adjusted by operating the dimming element 324with a controlled potential difference between the upper electrode 315and the lower electrode 349, which allows the dimming element 324 tofunction as an ND filter or a shutter. Hence, it is possible to optimizethe amount of the light incident on the photoelectric transducer 400 byappropriately controlling the potential difference between the upperelectrode 351 and the lower electrode 349 depending on the externalenvironment. Moreover, since the single number of the lower electrode349 is arranged so as to cover the whole of the through hole 216 or allof the light-receiving surface of the photoelectric transducer 400, itis possible to avoid generation of a refractive-index distribution.Hence, no adverse influence is exerted on the outside light incident onthe dimming element 324, and a high-quality image can be obtainedwithout any adverse influence such as generation of a fringe orunevenness on the image captured by the photoelectric transducer 400.

Second Embodiment

In the present embodiment, a modified example of the dimming element 324shown in the First Embodiment is demonstrated. An explanation of thestructure the same as or similar to those described in the FirstEmbodiment may be omitted.

A schematic top view of the dimming element 324 of the presentembodiment is shown in FIG. 11A, whereas a schematic view of a crosssection along a chain line D-D′ in FIG. 11A is shown in FIG. 11B. Asshown in these figures, the dimming element 324 of the presentembodiment is divided into a plurality of regions (e.g., a first region349-1, a second region 349-2, and a third region 349-3) electricallyindependent from one another. In the structure shown in FIG. 11A, thenumber of these regions is three. However, there is no limitation to thenumber of the regions. The plurality of regions is electricallyconnected to the respective dimming-controlling lines 358 (e.g., a firstdimming-controlling line 358-1, a second dimming-controlling line 358-2,and a third dimming-controlling line 358-3) independently controlledfrom one another. On the other hand, the upper electrode 351 may bearranged so as to overlap with the plurality of regions. Therefore, onedimming element 324 includes a plurality of liquid crystal elements inthe present embodiment.

The shape and the arrangement of the plurality of regions are notlimited, and the outer circumference of each region may be configured tobe a circle or a part of a circle while one region is surrounded byanother region as shown in FIG. 11A and FIG. 11B. In this case, a k-thregion selected from first to n-th regions is surrounded by a (k+1)-thregion where the total number of the regions is n, the innermost regionis the first region, and an outermost region is the n-th region. Here, nis a natural number larger than 1, and k is a natural number equal to 1and less than n. For example, the innermost first region 349-1 issurrounded by the second region 349-2, whereas the second region 349-2is surrounded by the third region 349-3.

Such a structure allows the transmissivity of the liquid crystal elementto be controlled in every plural region in the dimming element 324,which enables more precise control of the light transmissivity of thedimming element 324. Hence, the dimming element 324 can be used as an NDfilter or a shutter having more precisely controlled transmissivity.

In addition, a plurality of slits 349 a arranged in a stripe form may beprovided in each region as shown in FIG. 12A.

In a similar way, a plurality of slits 351 a arranged in a stripe formmay be formed in the upper electrode 351 as shown in FIG. 12B. Anenlarged schematic top view of the case where the slits 349 a and 351 aare respectively provided to the lower electrode 349 and the upperelectrode 351 is shown in FIG. 13A, and a schematic view of a crosssection along a chain line E-E′ in FIG. 13A is shown in FIG. 13B.

As shown in FIG. 13A, a width W₁ of the slit 349 a is preferred to bethe same as or substantially the same as a width W₂ of the slit 351 a.Specifically, the widths W₁ and W₂ are equal to or more than 2 μm andequal to or less than 20 μm and typically 10 μm. On the other hand, awidth W₃ of a region between adjacent slits 349 a is preferred to be thesame as or substantially the same as a width W₄ of a region betweenadjacent slits 351 a. Specifically, the widths W₃ and W₄ are equal to ormore than 200 μm and equal to or less than 600 μm and typically 400 μm.Furthermore, the slits 349 a and the slits 351 a are provided so that apitch P₁ of the slits 349 a and a pitch P₂ of the slits 351 a are thesame as each other.

The upper electrode 351 and the lower electrode 349 are arranged so thatslit 349 a overlaps with the region between two adjacent slits 351 a,and the slit 351 a similarly overlaps with the region between twoadjacent slits 349 a. Here, it is preferred that a linear line L₁passing through a center of the region between the adjacent slits 349 aand extends in a plane parallel to the surface of the array substrate302 pass through a center of the slit 351 a when the display device 100is viewed from above. In a similar way, it is preferred that a linearline L₂ passing through a center of the region between the adjacentslits 351 a and extends in a plane parallel to the surface of the arraysubstrate 302 pass through a center of the slit 349 a.

In the dimming element 324, the initial orientation of the liquidcrystal molecules is the same as that in the pixel 322 and issubstantially parallel to the surface of the array substrate 302.Application of a potential difference between the upper electrode 351and the lower electrode 349 causes the liquid crystal molecules to risefrom the plane parallel to the array substrate 302. However, when thepre-tilt angle of the liquid crystal molecules is extremely small in anoff state, the rising direction varies, which may result in regions(domains) different in the rising direction. If the domains are randomlyformed, the viewing angle characteristics and uniformity of thetransmissivity in the dimming element 324 are influenced. However, theuse of the lower electrode 349 and the upper electrode 351 having theaforementioned structures and arrangements causes the electric fieldgenerated therebetween to be tilted from a normal line of the arraysubstrate 302, by which the rising direction can be controlled. Forexample, when focus is placed on one region between the adjacent slits349 a, the liquid crystal molecules on the right side of the slit 351 ain the drawing (the liquid crystal molecules overlapping with the regionbetween one of the adjacent slits 349 a and the slit 351 a) rises insubstantially a single direction, while the liquid crystal molecules onthe left side (the liquid crystal molecules overlapping with the regionbetween the other of the adjacent slits 349 a and the slit 351 a) risesin a substantially reverse direction as shown in FIG. 13B. Therefore,the domain size is decreased, and the distribution thereof issuppressed. As a result, it is possible to prevent deterioration orin-plane unevenness of the viewing angle dependence of thetransmissivity.

Third Embodiment

In the present embodiment, a modified example of the dimming element 324described in the First and Second Embodiments is demonstrated. Anexplanation of the structure the same as or similar to those describedin the First and Second Embodiments may be omitted.

A schematic top view of the dimming element 324 of the presentembodiment is shown in FIG. 14 , and a schematic view of a cross sectionalong a chain line F-F′ in FIG. 14 is shown in FIG. 15 . The dimmingelement 324 of the present embodiment is different from the dimmingelement 324 of the First Embodiment in that an FFS liquid crystalelement is formed. Specifically, the interelectrode insulating film 368is provided over the lower electrode 349 over which the upper electrode351 is formed in the dimming element 324 of the present embodiment asshown in FIG. 14 and FIG. 15 . The upper electrode 351 possesses acomb-teeth shape having a plurality of cutoffs and is connected to thedimming-controlling line 358 through the opening 356 formed in theleveling film 366 and the interelectrode insulating film 368. Hence, apart of the lower electrode 349 is exposed from the upper electrode 351.The power-source line 344 is connected to the lower electrode 349 bywhich the potential (Vcom) the same as that of the common electrode 348disposed in the pixels 322 can be supplied.

The first orientation film 370-1 is arranged so as to cover the lowerelectrode 349 and the upper electrode 351, and the liquid crystal layer308 is arranged so as to be sandwiched by the first orientation film370-1 and the second orientation film 370-2 and cover the lowerelectrode 349 and the upper electrode 351. The orientation treatmentdirections of the first orientation film 370-1 and the secondorientation film 370-2 are the same as each other and also the same asthe orientation treatment directions of the first orientation film 370-1and the second orientation film 370-2 in the pixel 322. The liquidcrystal molecules are rotated by the electric field generated by thepotential difference between the lower electrode 349 and the upperelectrode 351 and parallel to the surface of the array substrate 302,thereby controlling the transmissivity of the dimming element 324.

In the dimming element 324 of the present embodiment, no λ/4 plate norλ/2 plate is provided. Instead, a third linear polarizing plate 310-3under the array substrate 302 and a second linear polarizing plate 310-2over the counter substrate 304 are provided so as to sandwich the arraysubstrate 302, the counter electrode 304, and the dimming element 324. Atransmission axis of the third linear polarizing plate 310-3perpendicularly intersects with the transmission axis of the firstlinear polarizing plate 310-1 provided in the pixel 322. On the otherhand, the second linear polarizing plate 310-2 is the same as the secondlinear polarizing plate 310-2 disposed in the pixel 322. In other words,the second linear polarizing plate 310-2 disposed in the pixel 322 andthe second linear polarizing plate 310-2 disposed over the dimmingelement 324 are integrated into a single polarizing plate shared by thepixel 322 and the dimming element 324. Hence, the transmission axis ofthe second linear polarizing plate 310-2 is the same between the pixel322 and the dimming element 324, and the third linear polarizing plate310-3 and the second linear polarizing plate 310-2 are in the parallelNichol relationship to each other.

Note that, although not illustrated, the first linear polarizing plate310-1 integrated with the first linear polarizing plate 310-1 providedin the pixel 322 may be arranged under the array substrate 302, thesecond linear polarizing plate 310-2 may be arranged so as not tooverlap with the dimming element 324, and the third linear polarizingplate 310-3 may be arranged over the counter electrode 304 so as tooverlap with the dimming element 324. In this case, the first linearpolarizing plate 310-1 is shared by the pixel 322 and the dimmingelement 324, and the transmission axes thereof is the same therebetween.On the other hand, the second linear polarizing plate 310-2 and thethird linear polarizing plate 310-3 are in a relationship in which thetransmission axes are different from each other by 90° between thepixels 322 and the dimming element 324.

FIG. 16 and FIG. 17 are schematic cross-sectional views respectivelycentering the dimming element 324 and the pixel 322. As shown in thisFIG. 16 , a part of the first linear polarizing plate 310-1 and a partof the third linear polarizing plate 310-3 may overlap with each otherbetween the dimming element 324 and the pixel 322. The third linearpolarizing plate 310-3 may overlap with the part of the first linearpolarizing plate 310-1 so that the part of the first linear polarizingplate 310-1 is located between the third linear polarizing plate 310-3and the array substrate 302, or a reverse relationship may be employed.In this case, the black matrix 376 may be disposed so as to overlap withthe first linear polarizing plate 310-1 and the third linear polarizingplate 310-3. Alternatively, the first linear polarizing plate 310-1 andthe third linear polarizing plate 310-3 may be placed with a gaptherebetween as shown in FIG. 17 . In this case, a part of the arraysubstrate 302 is exposed from the first linear polarizing plate 310-1and the third linear polarizing plate 310-3. The black matrix 376 may bedisposed so as to overlap with the exposed portion, the third linearpolarizing plate 310-3, and the first linear polarizing plate 310-1 inorder to shield light.

The operation of the dimming element 324 having the aforementionedstructure is explained using FIG. 18A and FIG. 18B. These figuresrespectively correspond to FIG. 8A and FIG. 8B, and a part of thecomponents such as the liquid crystal layer 308 is omitted.

(1) Initial State

FIG. 18A is a schematic perspective view of the dimming element 324 inan off state. In this state, the orientation of the liquid crystalmolecules is determined by the orientation characteristics of the firstorientation film 370-1 and the second orientation film 370-2. Since theorientation treatment directions of the first orientation film 370-1 andthe second orientation film 370-2 are the same as each other, the liquidcrystal molecules substantially orient along the orientation treatmentdirections in the absence of an electric field.

Here, a case is considered in which light indicated by a hollow arrowproceeds from the side of the third linear polarizing plate 310-3 towardthe side of the second linear polarizing plate 310-2. This light becomeslinearly polarized light (a) parallel to the transmission axis whenpassing through the third linear polarizing plate 310-3 and then entersthe liquid crystal layer 308. When the orientation treatment isperformed on the orientation films 370 so that the orientation treatmentdirections are parallel to the transmission axis, the polarizing axis ofthe linearly polarized light (a) and the orientation direction of theliquid crystal molecules are substantially parallel. Hence, no phasevariation of the light occurs, and this linearly polarized light (a) isincident on the second linear polarizing plate 310-2 as linearlypolarized light (b), maintaining the polarizing axis and intensity.Since the transmission axis of the second linear polarizing plate 310-2is parallel to that of the third linear polarizing plate 310-3, thelinearly polarized light (b) passes through the second linear polarizingplate 310-2 and radiates outside. Thus, the dimming element 324 isnormally white in the off state.

(2) Operation

FIG. 18B is a schematic perspective view in an on state produced byproviding a potential difference between the lower electrode 349 and theupper electrode 351. This potential difference generates an electricfield substantially parallel to the surface of the array substrate 302,and the liquid crystal molecules rotate in the plane parallel to thesurface of the array substrate 302 due to the dielectric anisotropy ofthe liquid crystal molecules. Hence, the polarizing axis of the linearlypolarized light (a) incident on the liquid crystal layer 308 and theorientation direction of the liquid crystal molecules are shifted fromeach other, which causes a phase retardation of the light incident onthe liquid crystal layer 308. In the display device 100, it is preferredto control the thickness of the liquid crystal layer 308 in accordancewith the refractive indexes of the liquid crystal molecules in the longaxis direction and the short axis direction so that the phaseretardation is π. In such a case, when passing through the liquidcrystal layer 308, the light becomes linearly polarized light (b) whichis obtained by rotating the polarizing axis of the linearly polarizedlight immediately before entering the liquid crystal layer 308. When theorientation of the liquid crystal molecules rotates by 90°, thepolarizing axis of this linearly polarized light (b) perpendicularlyintersects with the polarizing axis of the linearly polarized light (a).Since the third linear polarizing plate 310-3 and the second linearpolarizing plate 310-2 are in the parallel Nichol relationship, thelinearly polarized light (b) cannot pass through the second linearpolarizing plate 310-2.

The amount of the extracted light is determined by the rotation angle ofthe liquid crystal molecules, and the rotation angle can be controlledby the potential difference between the lower electrode 349 and theupper electrode 351 based on the potential of the dimming-controllingsignal. Therefore, control of this potential enables the transmissivityof the dimming element 324 to be controlled, which allows the dimmingelement 324 to function as a neutral density filter (ND filter) or ashutter. For example, the amount of light incident on the photoelectrictransducer 400 can be optimized by appropriately controlling thepotential difference between the upper electrode 351 and the lowerelectrode 349 in accordance with an external environment. In addition,when the dimming element 324 is controlled by further increasing thispotential difference so that light cannot substantially transmit thedimming element 324, it is possible to prevent an adverse influence onthe display formed by the pixels 322 because the outside light reflectedby the photoelectric transducer 400 can be shielded.

Fourth Embodiment

An example of a manufacturing method of the display device 100 havingthe structure described in the First Embodiment is explained in thepresent embodiment. An explanation of the structure the same as orsimilar to those described in the First to Third Embodiments may beomitted.

FIG. 19A to FIG. 22 are schematic cross-sectional views showing themanufacturing method of the display device 100, and the left side andthe right side respectively demonstrate a part of the pixel 322 and apart of the dimming element 324 in each drawing.

1. Array Substrate

FIG. 19A is a schematic view in which the components up to theinterlayer insulating film 364 are formed over the array substrate 302.An explanation is omitted because this structure can be fabricatedapplying the known methods and materials.

Etching is performed on the interlayer insulating film 364 to formopenings reaching the semiconductor film 352, and a metal film isprepared to cover these openings. The metal film can be formed bystacking metal films including a metal such as molybdenum, tungsten,titanium, or aluminum with a sputtering method, a chemical vapordeposition (CVD) method, and the like. After that, the metal film issubjected to etching processing to form the image-signal line 342, thedrain electrode 354, and the dimming-controlling element 358 (FIG. 19B).With this process, the transistor 346 is fabricated. As described above,the part of the image-signal line 342 functions as the source electrodeof the transistor 346.

After that, the leveling film 366 is formed so as to cover thetransistor 346 and the dimming-controlling line 358 (FIG. 19C). Theleveling film is formed by applying a precursor of the polymer describedin the First Embodiment with a wet-type film formation method such as aspin-coating method, a dip-coating method, an ink-jet method, and aprinting method, and then curing the precursor.

After that, the common electrode 348 is fabricated over the levelingfilm 366 (FIG. 19C). The common electrode 348 is configured so as totransmit visible light. Therefore, the common electrode 348 may beformed with a sputtering method and the like using a conductive oxideexhibiting transmitting properties with respect to visible light, suchas a mixed oxide of indium and tin (ITO) and a mixed oxide of indium andzinc (IZO). Although not illustrated, the power-source line 344 isformed after forming the common electrode 348. The power-source line 344is fabricated by stacking the films including the aforementioned metalwith a sputtering method, a CVD method, or the like. Note that, when thedimming element 324 forms an FFS liquid crystal element as described inthe Third Embodiment, the lower electrode 349 may be simultaneouslyformed when the common electrode 348 is formed. Hence, the commonelectrode 348 and the lower electrode 349 can exist in the same layerand possess the same composition and thickness in this case.

After that, the interelectrode insulating film 368 is formed so as tocover the common electrode 348 and the dimming-controlling line 358(FIG. 20A). The interelectrode insulating film 368 includes theaforementioned silicon-containing inorganic compound and is formed usinga CVD method or a sputtering method. Next, etching is performed on theinterelectrode insulating film 368 and the leveling film 366 to form theopenings 357 and 356 respectively reaching the drain electrode 354 andthe dimming-controlling line 358 (FIG. 20A).

After that, the pixel electrode 350 and the lower electrode 349 arefabricated so as to be in contact with the drain electrode 354 and thedimming-controlling line 358, respectively (FIG. 20B). These electrodesare also preferred to have a high transmitting property with respect tovisible light, and therefore, may be formed with a sputtering methodusing a conductive oxide having a light-transmitting property, such asITO and IZO. Since the pixel electrode 350 and the lower electrode 349can be simultaneously formed, these electrodes can exist in the samelayer and have the same composition and thickness. Although notillustrated, when the dimming element 324 forms an FFS liquid crystalelement, the upper electrode 351 may be simultaneously formed when thepixel electrode 350 is fabricated. Therefore, the pixel electrode 350and the upper electrode 351 can exist in the same layer and have thesame composition and thickness in this case.

After that, the first orientation film 370-1 is formed so as to coverthe pixel electrode 350 and the lower electrode 349 (FIG. 20B). Thefirst orientation film 370-1 may be formed by applying a polyimideprecursor with a wet-type film formation method, curing the precursor,and then performing a rubbing treatment. The known methods may beapplied in the rubbing treatment.

2. Counter Electrode

The color filter 374 and the black matrix 376 are formed over thecounter substrate 304 (FIG. 21A). The black matrix 376 is prepared so asto cover the transistor 346, the image-signal line 342, the gate line340, and the like in the pixel 322, while the black matrix 376 isprepared so as to cover the dimming-controlling line 358 in the dimmingelement 324. In the dimming element 324, a transparent film may beformed as the color filter 374, or no color filter 374 may be provided.In the case where the overcoat 372 is formed, the overcoat 372 is formedso as to cover the color filter 374 and the black matrix 376 (FIG. 21B).The color filter 374, black matrix 376, and overcoat 374 can be preparedusing the known methods and materials. Thus, a detailed explanation isomitted.

After that, the upper electrode 351 of the dimming element 324 isfabricated (FIG. 21C). The upper electrode 351 may be formed by applyingthe same method for the fabrication of the lower electrode 349, thecommon electrode 348, and the pixel electrode 350. After that, thesecond orientation film 370-2 is formed so as to cover the color filter374, the black matrix 376, and the upper electrode 351. The secondorientation film 370-2 may be also formed with the same method as thatof the first orientation film 370-1. The spacer 378 which is an optionalelement is formed over the second orientation film 370-2 by applying theknown methods and materials (FIG. 21C). The spacer 378 may be fabricatedover the first orientation film 370-1 formed over the array substrate302.

3. Cell Fabrication

After that, the liquid crystal layer 308 is formed. Specifically, thesealing material 306 is applied over one of the array substrate 302 andthe counter substrate 304, and the liquid crystal is dropped on theregion formed by the sealing material 306. After that, the other of thearray substrate 302 and the counter substrate 304 is arranged over theliquid crystal and the sealing film 306 so that the pixel electrode 350,the common electrode 348, the lower electrode 349, and the upperelectrode 351 are sandwiched by the array substrate 302 and the countersubstrate 304, and then the sealing material 306 is cured. At this time,the pixel electrode 350 and the common electrode 348 do not overlap withthe upper electrode 351 and are exposed from the upper electrode 351.With this process, the array substrate 302 and the counter electrode 304are bonded and fixed to each other. Alternatively, the array substrate302 and the counter electrode 304 are bonded using the sealing material306 in advance. In this case, the sealing material 306 is formed so asnot to have a closed shape but to be divided into two portions. Aftercuring the sealing material 306, the liquid crystal is injected from thegap between the separated two sealing materials 306, the sealingmaterial 306 is further applied between the cured sealing films 306, andthen the sealing film 306 is cured. With this process, the sealing film306 provides a single closed shape. Note that, when the spacer 378 isnot fabricated, particle spacers may be mixed in the liquid crystal.

Through the aforementioned processes, the display device 100 can bemanufactured.

Implementation of the embodiments of the present invention, a displaydevice with a small frame region and a wide display region can beproduced. Since a variety of photoelectric transducers can be mounted soas to overlap with the display region in this display device, theembodiments of the present invention provide a high degree of freedom indesigning a display device. In addition, it is possible to control theamount of light incident on the photoelectric transducer withoutreduction of display quality by controlling transmissivity of thedimming element disposed in the display region and overlapping with thephotoelectric transducer.

It is understood that another effect different from that provided b yeach of the aforementioned embodiments is achieved by the presentinvention if the effect is obvious from the description in thespecification or readily conceived by persons ordinarily skilled in theart.

What is claimed is:
 1. An imaging device comprising: two image sensors;two diming elements respectively above the image sensors, the dimmingelements comprising an array substrate having lower electrodes, acounter substrate having upper electrodes, and a liquid crystal layerbetween the array substrate and the counter substrate, two pairs ofwaveplates sandwiching the array substrate, each pair of the two pairsof waveplates only overlapping one of the two image sensors,respectively, in a plan view; a pair of linear polarizing platessandwiching the two pairs of waveplates; a plurality of pixels in adisplay region surrounding the two dimming elements; and color filtersin the plurality of pixels, wherein the color filters are not placed inthe dimming element.
 2. The imaging device according to claim 1, whereinthe two pairs of waveplates are each a λ/4 waveplate.
 3. The imagingdevice according to claim 2, wherein transmission axes of the pair oflinear polarizing plates orthogonally intersect each other, and slowaxes of the two pairs of λ/4 waveplates orthogonally intersect eachother.
 4. The imaging device according to claim 1, wherein the two pairsof waveplates are each a λ/2 waveplate.
 5. The imaging device accordingto claim 4, wherein transmission axes of the pair of linear polarizingplates orthogonally intersect each other, and slow axes of the two pairsof λ/2 waveplates orthogonally intersect each other.
 6. The displaydevice according to claim 1, wherein each of the lower electrode and theupper electrode has a plurality of slits arranged in a stripe form. 7.The display device according to claim 6, wherein at least one of theplurality of slits of the upper electrode overlaps with a region betweenthe adjacent slits of the lower electrode.
 8. The display deviceaccording to claim 6, wherein a pitch of the plurality of slits of thelower electrode and a pitch of the plurality of slits of the upperelectrode are the same as each other.
 9. The display device according toclaim 1, wherein the diming element is different in size from each ofthe plurality of pixels.